DE202014104619U1 - pipe coupling - Google Patents

Abstract

Pipe coupling (1, 23) for the passage of gases, with a male pipe part (2, 24) which extends at least partially along a first central axis (A) and a female pipe part (3) which at least partially extends along a second central axis (B), the male pipe part (2, 24) on its outside or the female pipe part (3) on its inside has a circumferential projection (9) in the pipe circumferential direction (X, Y), which correspondingly has other female (3) or male (2, 24) tubular part correspondingly has on its inside or outside a recess (16) which extends in the pipe circumferential direction (X, Y) and corresponds to the projection (9), and if both central axes (A, B) have a common axis (C) are united, the male pipe part (2, 24) with the female pipe part (3) can be coupled and uncoupled by means of a coupling / decoupling process, the male pipe part (2, 24) in the coupling / decoupling process being ei ne first translational movement along the common axis (C) with the female tube part (3) via an engagement between the projection (9) and the recess (16) is positively coupled, and by a second translational movement that is opposite to the first movement , is uncoupled from this, and the pipe coupling (1, 23) is sealed in the coupled state by its abutting pipe surfaces against the external environment (25), characterized in that the coupling / uncoupling process is repeatable, and the spatial dimensions of the two pipe parts (2, 24; 3) after a coupling / decoupling process and the spatial dimensions of the two pipe parts (2, 24; 3) before the coupling / decoupling process are the same.

Description

The present invention relates to a pipe coupling for the passage of gases according to the preamble of claim 1.

From the EP 0 223 942 A1 is known a pipe transition piece in transport pipes for gas and liquids. The transition piece consists essentially of a male pipe end, a female sleeve and a press ring.

The male pipe end has a projecting sawtooth profile on its outer peripheral surface. The female sleeve has sawtooth projections and grooves on its inner peripheral surface.

The sleeve is pushed over the male pipe end with the aid of a press. The male pipe end is preferably made of metal, the sleeve is made of plastic. During the push-on operation by the pressing, the projections on the sleeve are shifted in position and deformed, whereby a gas seals between the sleeve and the male pipe end comes about.

The gas seal is permanently maintained by the fact that the pushed over the sleeve outer surface press ring this deformation state in which abut surfaces of the sawtooth projections of the male pipe end and Sägezahnrillen the sleeve together gas-tight maintains. An additional gas seal is achieved by means of a sealing ring.

When loosening the male pipe end of the sleeve, however, the sleeve and partly the male pipe end is destroyed. In one embodiment, over the number of saw teeth in the profiles of the pipe end and the sleeve a predetermined breaking point for defined overpressure conditions is generated.

The present invention is based on the object to provide a simple, reliable, easy to handle, detachable and well sealed pipe coupling for the passage of gases, wherein the parts of the pipe coupling to be reusable after use.

The present invention proposes to solve this problem, a pipe coupling according to the features of claim 1.

In claim 1, a pipe coupling is proposed according to the preamble, in which the coupling-uncoupling process is repeated, and the spatial dimensions of the two pipe parts after a clutch uncoupling operation and the spatial dimensions of the two pipe parts before the clutch-disengaging process are the same.

Characterized in that the spatial dimensions of the two pipe parts are equal before and after the clutch uncoupling process and the clutch-disengaging operation is repeated, the male and female pipe part can be repeatedly and without modifications for further self-sealing coupling operations take.

The fact that the spatial dimensions are the same before and after the clutch uncoupling process can also be understood to mean that deviations between the spatial dimensions of the pipe parts before and after the clutch uncoupling process are included, as far as these deviations do not differ from one by the construction of the Pipe coupling in a clutch uncoupling deliberately or unavoidably be brought about geometry change.

In a further embodiment, the male or female pipe part may be reversibly elastically deformed upon decoupling from the corresponding other female or male pipe part. As a result, the repeatability of the clutch disengagement process as well as the equality of the spatial dimensions of the two tube parts before and after the clutch uncoupling process is ensured in a simple and reliable manner.

Conveniently, the projection may be in its cross-sectional profile mirror-symmetrical to a plane which is orthogonal to the central axis. This allows a simple geometry and manufacturability of the pipe coupling. In addition, it is ensured by the mirror symmetry that for relative movement of the two tube parts to each other in both directions of the common axis similar forces are necessary.

Advantageously, the projection in its cross-sectional profile in the plane of the central axis may be rounded or round. It has been shown that rounded cross-sectional profiles seal the two pipe parts particularly reliably against each other and increase the reusability of the pipe parts.

In a preferred embodiment, the projection may be rounded in its cross-sectional profile in the plane of the central axis on its two profile sides lying opposite the central axis. This allows a small amount of force in the clutch-disengaging process at the same time reliable tightness between the two pipe parts. Furthermore, unwanted abrasion is reduced and thus ensures the long reusability of the pipe coupling parts.

In a particularly preferred embodiment, the projection in its cross-sectional profile in the plane of the central axis may be semicircular or circular segment-shaped. It has been found that especially a semicircular or circular segmental design of the cross-sectional profile meets the requirements for reliability, tightness, solubility, reusability, simplicity and ease of handling to a particular extent.

It is proposed that the radius of the projection divided by the radius of the recess may be in the range of 0.7 to 1.3, in particular in the range of less than 1, and in particular in the range of 0.75 to 0.95. It has been found that the aforementioned requirements for reliability, tightness, solubility, reusability, simplicity and ease of handling in these narrowing areas are always better met.

In a preferred embodiment, the circular segment height of the protrusion divided by the circular segment height of the recess may be in the range of 1.3 to 0.7, in particular in the range of 1.1 to 0.9. It could be observed that the design of the circular segment heights in these narrowing areas advantageously fulfills the aforementioned requirements.

In a further embodiment, the two pipe parts can be sealed in the coupled state alone by the adjoining pipe surfaces against the outside environment. This facilitates the handling of the pipe coupling in use and also reduces the manufacturing costs.

It is proposed that the two pipe parts can be sealed in the coupled state by the positive engagement against the external environment. This causes a particularly reliable tightness between the two pipe parts, since at pressure conditions which exert a force on the positive connection, the two pipe parts are pressed against each other at the point of engagement and thus the tightness is increased.

Furthermore, the male pipe part or the female pipe part at a pipe end have exactly one projection and have the corresponding other, female or male pipe part at a pipe end exactly one recess. Surprisingly, it has been shown that a task pipe coupling contrary to expectations with a projection and a recess can be implemented. This allows a simple design of the pipe coupling and a particularly simple handling. Furthermore, in the presence of exactly one projection and exactly one recess, compared to a plurality of projections and recesses, the fitting fit of the positive engagement can be checked simply by slightly moving the two tube parts against each other by the fitter.

Preferably, the male pipe part by hand, without tools, with the female pipe part can be coupled and decoupled again. This allows a simple and quick coupling and decoupling of the pipe coupling and thus easy handling.

In another embodiment, the male pipe part may have on its outside a stop for a pipe end of the female pipe part, and the projection may be positioned between a pipe opening at a pipe end of the male pipe part and the stop. The stop limits the maximum penetration depth of the male pipe part into the female pipe part. Furthermore, can be supported by the position of the stop on the male pipe part a secure conclusion of the positive engagement. At the same time the operator receives an optical feedback on the penetration depth of the male pipe part by the position of the stop to the female pipe part.

Preferably, the stop on the lateral surface of the male pipe part may be formed completely circumferentially in the pipe circumferential direction. The fully circumferential configuration of the stopper stiffens the male pipe part and thus improves handling of the pipe coupling during a clutch disconnect operation.

In a variant of the invention, the outer surface of the female pipe part in the radial direction to the common axis project beyond the stop. This prevents a direct destructive force on the stop in the radial direction, as it can happen, for example, in open lying on the floor pipe couplings by unintentional kicks.

In a preferred embodiment, the outer circumferential surface of the female pipe part may project beyond the stop by at least 0.5 mm, in particular by at least 1 mm. This gives a favorable protective effect.

In a further embodiment, in the coupled state, the pipe end of the female pipe part may be positioned adjacent or spaced from the stop, in particular the clearance between the female pipe part and the stop, measured along the common axis, 0.5mm to 10mm, especially 1mm to 4mm. Thus, the seat of the positive engagement on the position of the stopper on the male pipe part can be precisely defined. At a spacing of the stopper to the female pipe part of the distance is only used to limit the maximum penetration depth and therefore allows greater manufacturing tolerances, since the distance between the projection and the stop is not critical for the conclusion of the engagement between the projection and the recess. Furthermore, when coupling projection and recess can be found free for the engagement. It has been found that in this case a clear distance in the range of 0.5 to 10 mm unfolds the desired effect, in particular in the range of 1mm to 4mm.

Conveniently, in the coupled state, the distance between an outermost edge of the female pipe part on the side facing the male pipe part and an outermost edge of the stop on the side facing away from the female pipe part, each measured along the common axis, 1mm to 12mm, in particular 1.5mm up to 6mm. Thus, the stop is protected by the female pipe part in a favorable manner against unwanted external forces.

In a further embodiment, the male pipe part and the female pipe part may be made of plastic, and the difference in the Shore A hardness of the two pipe parts 5 to 20, in particular 7 to 15, and in particular be the male pipe part harder than the female pipe part. This allows a particularly easy-to-use pipe coupling, in which both pipe parts are reusable after a clutch uncoupling and also reliably seals against the external environment. A harder than the female pipe part male pipe part also facilitates the clutch-disengaging process and thus the handling.

Advantageously, at least one of the pipe parts may be made of polyvinyl chloride (PVC), polyethylene (PE), polyamide (PA) or a thermoplastic elastomer (TPE). Furthermore, all possible pairings of the aforementioned materials for the male and female pipe part are expressly disclosed here. This ensures reliability, solvability, ease of handling, simplicity, tightness and reusability of the pipe parts.

In a preferred embodiment, in the coupled state, the interior of the two pipe parts can still be sealed against the environment by the abutting pipe surfaces even at 0.5 bar overpressure, in particular still at 0.75 bar overpressure, especially at 1 bar overpressure. Preferably, the tightness relates to overpressure in gases. This opens up a wide range of possible uses of the pipe coupling for the passage of various gases under overpressure, such as air.

Hereinafter, to facilitate understanding of the invention, possible embodiments of the invention, which combine several of the aforementioned embodiments, will be described in more detail.

Showing:

1 a sectional view, cut in a plane of a central axis, an embodiment of a pipe coupling according to the invention with a male pipe part and a female pipe part in the uncoupled state, before or after the clutch disconnection process,

2 a sectional view of a pipe end portion of the male pipe part 1 .

3 a sectional view of a pipe end portion of the female pipe part 1 .

4 a sectional view of the pipe coupling 1 in the coupled state,

5 a sectional view, cut in a plane of a central axis, another embodiment of a pipe coupling according to the invention with a male pipe part and a female pipe part in the uncoupled state, before or after the clutch disconnection process,

6 the pipe coupling off 5 in the coupled state.

1 shows a pipe coupling according to the invention 1 for passing air in a possible embodiment. The pipe coupling comprises a male pipe part 2 and a female pipe part 3 ,

The male pipe part 2 is an L-shaped curved, partly rotationally symmetrical hollow body with two tube openings 4 . 5 at its two pipe ends 6 . 7 , The one pipe end 6 is for coupling with the female pipe part 3 provided and the other pipe end 7 is intended for coupling with another tubular body.

The male pipe part 2 is integrally formed and except for the two pipe openings 4 . 5 gas-tight or airtight closed. The male pipe part 2 extends to a bend along a first central axis A.

The male pipe part 2 has on its outer surface 8th near the pipe end 6 a fully circumferential in the tube circumferential direction X projection 9 , The tube circumferential direction X extends parallel to the tube circumference in a plane perpendicular to the first central axis A. In the case of the rotationally symmetrical tube end 6 shows the pipe circumferential direction X along a circular arc parallel to the pipe outside counterclockwise, when the male pipe part 2 along the first center axis A from the tube end side 6 out of view. The lead 9 is in its cross-sectional profile shown here in the plane of the first central axis A constant circular segment-shaped.

Furthermore, the male pipe part 2 on its lateral surface 8th a completely circumferential in the tube circumferential direction X stop 10 in the direction of the first central axis A to the projection 9 is spaced. The lead 9 is located at the end of the pipe 6 between the pipe opening 4 and the stop 10 ,

The female pipe part 3 is a along a second central axis B extending, rotationally symmetrical hollow body with two tube openings 11 . 12 at its two pipe ends 13 . 14 , The one pipe end 13 is for coupling with the male pipe part 2 provided and the other pipe end 14 is intended for coupling with another tubular body.

The female pipe part 3 is integrally formed and except for the two pipe openings 11 . 12 gas-tight or airtight closed.

The female pipe part 3 has at the pipe end 13 one on its inner surface 15 in the tube circumferential direction Y completely circumferential recess 16 , The pipe circumferential direction Y extends parallel to the pipe circumference in a plane perpendicular to the second central axis B. In the case of the rotationally symmetrical pipe body here, the pipe circumferential direction Y shows along a circular arc parallel to the pipe outside in a clockwise direction, if the female pipe part 3 along the second center axis B from the tube end side 13 out of view.

The recess 16 corresponds in its basic geometry to the lead 9 and is therefore also in its cross-sectional profile in the plane of the second central axis B also constant circular segment.

In the in 1 shown arrangement of the two pipe parts 2 . 3 to each other are the first and the second center axis A, B in a common axis C, which for reasons of clarity, only in 4 is shown. The male pipe part 2 is intended to be in the female pipe part 3 to be plugged in (plug-in coupling)

2 shows a cross-sectional portion of the for coupling with the female pipe part 3 provided pipe end 6 of the male pipe part 2 ,

The pipe inner diameter D of the male pipe part 2 is from the pipe opening 4 for coupling to the female pipe part 3 certain pipe end 6 until at least the stop 10 along the first central axis A constant, for example, 29.5mm.

The pipe outside diameter E of the male pipe part is from the pipe opening 4 until at least the stop 10 along the first central axis A constant, for example, 37.5mm. Consequently, that is down to the areas of the projection 9 and the stop 10 along the first central axis A constant wall thickness, at least between the pipe opening 4 and stop 10 , for example 4mm.

The tolerance in the geometries and wall thicknesses described here is preferably 0.2 mm.

The circular segment-shaped projection 9 has a circular arc formed with a radius F of, for example, 4.6mm. The height G of the circle segment of the projection 9 is for example 1.25mm. The length of the chord H of the projection along the first central axis A is 6mm, for example. The distance I of the symmetry axis J of the circle segment to the tube opening 4 along the first central axis A is for example 9mm.

The stop 10 is in the radial direction of the first central axis A by a length K of constant 2mm from the lateral surface 8th between projection 9 and stop 10 out. The strength L of the stroke 10 measured along the first central axis A is for example 2mm. The distance M between the stop 10 and the pipe opening 4 measured along the first central axis A is for example 23.5mm.

3 shows a cross-sectional portion of the for coupling to the male pipe part 2 provided pipe end 13 of the female pipe part.

The pipe inside diameter N of the female pipe part 3 is from the pipe opening 11 for coupling to the male pipe part 2 certain pipe end 13 until after the recess 16 along the second central axis B constant, for example, 37mm.

The pipe outside diameter O of the female pipe part 3 is from the pipe opening 11 until after the recess 16 along the second central axis B constant, for example, 45mm. Consequently, that is down to the area of the recess 16 along the second center axis B constant wall thickness, for example, 4mm.

The circular segment-shaped recess 16 has a circular arc which is formed with a radius P of for example 5mm. The height Q of the circle segment of the recess 16 is for example 1mm. The length R of the chord of the recess 16 along the second center axis B is 6mm, for example. The distance S of the symmetry axis T of the circle segment to the pipe opening 11 along the second central axis B is for example 13mm.

4 shows a cross-sectional view of the pipe coupling 1 out 1 in the coupled state. The lead 9 is in positive engagement with the recess 16 ,

The adjoining pipe surfaces of the two pipe parts 2 . 3 , here the circular arc-shaped profile surfaces of the projection 9 and the recess 16 and along the common axis C before and after the projection 9 / recess 16 located, abutting contact surfaces of the two pipe parts 2 . 3 , seal the interior 17 the pipe coupling, so the interiors 18 . 19 the two pipe parts 2 . 3 , against the external environment 25 the pipe coupling 1 , ie against the outsides of the two pipe parts 2 . 3 , from. The tightness of the pipe coupling is consequently realized without a separate sealing part, such as a sealing ring.

Between the extreme edge 20 of the female pipe end part 3 on the male pipe part 2 facing side and the stop 10 is a clear distance U or gap measured along the common axis C, for example, 2mm provided.

Between the extreme edge 20 and an outermost edge 21 of the stop 10 on the female pipe part 3 opposite side, each measured along the common axis C, the distance W is 4mm.

The lateral surface 22 of the female pipe part, which of the pipe outer diameter O of the female pipe part 3 described above the attack 10 radially to the common axis by a length V of, for example, 1.75mm.

The male pipe part 2 is made of PVC with a Shore A hardness of 84 , The female pipe part 3 is also made of PVC with a Shore A hardness of 73 ,

5 shows a cross-sectional view of a pipe coupling according to the invention 23 according to a further embodiment. Functional parts have the same reference numerals as in the previous embodiment.

The female pipe part 3 corresponds to the female pipe part 3 from the first embodiment. The male pipe part 24 This embodiment differs from the male pipe part 2 The previous embodiment, among other things, to the effect that it is formed completely rotationally symmetrical about the first center axis A. Another difference is that both pipe ends 6 are designed to be with a female pipe part 3 to couple and that the male pipe part 24 made of polyethylene (PE). The male pipe part 24 is mirror-symmetrical to a plane Z which is perpendicular to the first central axis A.

The pipe inner diameter D of the male pipe part is here, for example, 35.5 mm. The pipe outside diameter O of the male pipe part 24 is here for example 38.5mm. Consequently, that is down to the areas of the projections 9 and the attacks 10 along the first central axis A constant wall thickness, for example, 1.5mm. The pipe ends 6 can at the tube openings 4 be chilled.

The circular segment-shaped projections have here, for example, a radius F of 4mm. The height G of the circle segments of the projections 9 here is for example 1mm. The length H of the chords of the projections 9 here is 6mm, for example. The distances I are for example 9mm here.

The length K at the stops 10 here is also 1.75mm. The strength L of the attacks 10 here is for example 2mm. The distances M between the respective stop 10 and the nearest pipe opening 4 here are for example 23mm.

6 shows a cross-sectional view of the pipe coupling 5 in a coupled state. The male pipe part 2 is here with only a female pipe part 3 coupled

The clear distance U is here, for example, 1mm. The distance W is here for example 3mm. The supernatant V in the radial direction is here, for example, 1.5 mm.

In the following, for a better understanding of the invention, a possible operation of the in the 1 to 4 illustrated embodiment illustrated.

To the male pipe part 2 with the female pipe part 3 to couple and then the two pipe parts 2 . 3 to uncouple again, so perform a clutch uncoupling process, the two pipe parts 2 . 3 so positioned to each other, that the two center axes A, B lie together in the common axis C and the pipe end 6 of the male pipe part 2 the pipe end 13 of the female pipe part 3 opposite.

The male pipe part 2 is now translationally, for example, along the common axis C in the direction of the female pipe part 3 moves until the projection 9 with the recess 16 has completely come in a positive engagement. The female pipe part is held. This expands the harder male pipe part 2 the softer female pipe part 3 reversible elastic on. During the translatory movement, the male pipe end slides 6 with the lead 9 due to the round profile along the pipe inner surface 15 of the female pipe part 3 in the direction of the recess 16 for an exemplary force along the common axis C from 25N to 50N.

Because of the hard-to-dose force on the male tube part 2 along the common axis C acts normally by the fitter the projection 9 in the direction of the female pipe part 3 over the end of the recess 16 pushed out so that the stop 10 at the outer edge 20 the female pipe part abuts and another, excessive penetration of the male pipe part in the female pipe part 3 is prevented. Because both the lead 9 as well as the recess 16 are formed circular segment, the male pipe part 2 due to the elastically reversible deformation of the female pipe part 3 back towards the pipe opening 11 of the female pipe part 3 pressed, with the projection 9 with the recess 16 enters the positive engagement and the clear gap U is formed.

The two pipe parts 2 . 3 are now coupled with each other. The female pipe part 3 is in this state through the male pipe part 2 preferably only slightly widened. All contact surfaces between the male 2 and the female 3 Pipe parts in this case lie almost to each other over the entire surface, wherein in particular the abutting surfaces of the projection 9 and the recess 16 to the tightness of the pipe coupling 1 opposite the environment 25 contribute. The tightness is given in the coupling to 0.5 bar, in particular up to 0.75 bar and especially up to 1 bar gas pressure.

A mutually relative rotation of the two coupled pipe parts 2 . 3 about the common axis C is possible with simultaneous sealing.

Shall the two pipe parts 2 . 3 be decoupled from each other after use, so by hand, a force of, for example, 35N to 60N on the male pipe part 2 or according to the female pipe part 3 exerted along the common axis C, so that the round profile of the projection 9 disengages, the female pipe part 3 is reversibly elastically expanded and along the pipe inner surface 15 of the female pipe part 3 sliding out of said pipe part 3 is pulled out. The male pipe part 2 moves translationally along the common axis C in the direction opposite to the previous translational movement.

The male pipe part 2 can also be reversibly elastically deformed in the clutch-disengaging process. In such a case, this deformation is preferably lower than in the female pipe part 3 ,

The male and female pipe parts 2 . 3 after uncoupling have the same spatial dimensions as before the coupling and can be used for a clutch uncoupling more times.

In a further, not shown embodiment, the female pipe part at the location of the recess on its inner surface a circumferential in the tube circumferential direction Y, radially inwardly facing, circular segment-shaped projection. The male pipe part has correspondingly on its lateral surface at the location of the projection in a circumferential direction X circumferential, circular segment-shaped recess. The functions and procedures of this embodiment are analogous to those of the previously described embodiment.

That the recess corresponds to the projection is to be understood according to the invention in that projection and recess in the cross-sectional profile have similar basic geometries, such as a circle segment. It is also possible that projection and recess have only partially corresponding cross-sectional profiles, as long as it continues to realize a positive engagement with preferably sealing effect. Thus, in the case of a circular-segment-shaped recess, the projection may be circular-segment-shaped only at its flanks and be flattened in the middle, for example, or provided with a depression, so that the cross-sectional profile of the projection along the central axis is corrugated.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• EP 0223942 A1 [0002]

Claims (21)

Pipe coupling ( 1 . 23 ) for passing gases, with a male pipe part ( 2 . 24 ), which extends at least partially along a first central axis (A), and a female tube part ( 3 ) extending at least partially along a second central axis (B), the male pipe part ( 2 . 24 ) on its outside or the female pipe part ( 3 ) on its inside a circumferential in the pipe circumferential direction (X, Y) projection ( 9 ), which has correspondingly different, female ( 3 ) or male ( 2 . 24 ) Tube part according to its inside or outside a circumferential in the pipe circumferential direction (X, Y), the projection ( 9 ) corresponding recess ( 16 ), and if both central axes (A, B) are united in a common axis (C), the male pipe part ( 2 . 24 ) with the female pipe part ( 3 ) can be coupled and uncoupled again by a clutch uncoupling process, wherein in the clutch uncoupling process, the male pipe part ( 2 . 24 ) by a first translational movement along the common axis (C) with the female pipe part ( 3 ) about an engagement between the projection ( 9 ) and the recess ( 16 ) is positively coupled, and by a second translational movement, which is opposite to the first movement is decoupled therefrom, and the pipe coupling ( 1 . 23 ) in the coupled state by their abutting pipe surfaces against the external environment ( 25 ), characterized in that the coupling-uncoupling process is repeatable, and the physical dimensions of the two pipe parts ( 2 . 24 ; 3 ) after a clutch uncoupling operation and the physical dimensions of the two pipe parts ( 2 . 24 ; 3 ) are the same before the clutch disengagement process. Pipe coupling ( 1 . 23 ) according to claim 1, wherein the male ( 2 . 24 ) or the female pipe part ( 3 ) when decoupling from the corresponding other, female ( 3 ) or male ( 2 . 24 ) Tube part is reversibly elastically deformed. Pipe coupling ( 1 . 23 ) according to one of the preceding claims, wherein the projection ( 9 ) is in its cross-sectional profile mirror-symmetrical to a plane which is orthogonal to the central axis (A). Pipe coupling ( 1 . 23 ) according to one of the preceding claims, wherein the projection ( 5 ) in its cross-sectional profile in the plane of the central axis (A) is rounded or round. Pipe coupling ( 1 . 23 ) according to one of the preceding claims, wherein the projection ( 9 ) is rounded in its cross-sectional profile in the plane of the central axis (A) on its two along the central axis (A) opposite profile pages. Pipe coupling ( 1 . 23 ) according to one of the preceding claims, wherein the projection ( 9 ) in its cross-sectional profile in the plane of the central axis (A) is semicircular or circular segment-shaped. Pipe coupling ( 1 . 23 ) according to claim 6, wherein the radius (F) of the projection divided by the radius (P) of the recess in the range of 0.7 to 1.3, in particular in the range of less than 1, and especially in the range of 0.75 to 0, 95, lies. Pipe coupling ( 1 . 23 ) according to claim 6 or 7, wherein the circle segment height (G) of the projection divided by the circle segment height (Q) of the recess is in the range of 1.3 to 0.7, in particular in the range of 1.1 to 0.9. Pipe coupling ( 1 . 23 ) according to one of the preceding claims, wherein the two pipe parts ( 2 . 24 ; 3 ) in the coupled state alone by the adjoining pipe surfaces against the external environment ( 25 ) are sealed. Pipe coupling ( 1 . 23 ) according to one of the preceding claims, wherein the two pipe parts ( 2 . 24 ; 3 ) in the coupled state by the positive engagement against the external environment ( 25 ) are sealed. Pipe coupling ( 1 . 23 ) according to one of the preceding claims, wherein the male pipe part ( 2 . 24 ) or the female pipe part ( 3 ) at a pipe end ( 6 . 13 ) exactly one advantage ( 9 ) and the corresponding other, female or male pipe part ( 3 ; 2 . 24 ) at a pipe end ( 13 . 6 ) exactly one recess ( 16 ) Has. Pipe coupling ( 1 . 23 ) according to one of the preceding claims, wherein the male pipe part ( 2 . 24 ) by hand, without tools, with the female pipe part ( 3 ) can be coupled and uncoupled again. Pipe coupling ( 1 . 23 ) according to one of the preceding claims, wherein the male pipe part ( 2 . 24 ) on the outside of a stop ( 10 ) for a pipe end ( 13 ) of the female pipe part ( 3 ), and the lead ( 9 ) between a pipe opening ( 4 ) at a pipe end ( 6 ) of male pipe part ( 2 . 24 ) and the attack ( 10 ) is positioned. Pipe coupling ( 1 . 23 ) according to claim 13, wherein the stop ( 10 ) on the lateral surface ( 8th ) of the male pipe part ( 2 . 24 ) is formed completely circumferentially in the tube circumferential direction (X). Pipe coupling ( 1 . 23 ) according to claim 13 or 14, wherein the outer surface ( 22 ) of the female pipe part ( 3 ) in the radial direction to the common axis (C) the stop ( 10 ) surmounted. Pipe coupling ( 1 . 23 ) according to claim 15, wherein the outer surface ( 22 ) of the female pipe part ( 3 ) the attack ( 10 ) by a length (V) of at least 0 , 5mm, in particular by at least 1mm, surmounted. Pipe coupling ( 1 . 23 ) according to one of claims 13 to 16, wherein in the coupled state the pipe end ( 13 ) of the female pipe part ( 3 ) adjacent or spaced from the stop ( 10 ), in particular the clearance (U) between the female pipe part ( 3 ) and the attack ( 10 ) measured along the common axis (C) is 0.5mm to 10mm, especially 1mm to 4mm. Pipe coupling ( 1 . 23 ) according to one of claims 13 to 17, wherein in the coupled state the distance (W) between an outermost edge ( 20 ) of the female pipe part ( 3 ) on the male pipe part ( 2 ) facing side and an outermost edge ( 21 ) of the stop ( 10 ) on the female pipe part ( 3 ) facing away, each measured along the common axis (C), 1mm to 12mm, in particular 1.5mm to 6mm. Pipe coupling ( 1 . 23 ) according to one of the preceding claims, wherein the male pipe part ( 2 . 24 ) and the female pipe part ( 3 ) are made of plastic, and the difference of the Shore A hardnesses of the two pipe parts 5 to 20, in particular 7 to 15, and in particular the male pipe part ( 2 . 24 ) is harder than the female pipe part ( 3 ). Pipe coupling ( 1 . 23 ) according to one of the preceding claims, wherein at least one of the pipe parts of polyvinyl chloride (PVC), polyethylene (PE), polyamide (PA) or of a thermoplastic elastomer (TPE) is. Pipe coupling ( 1 . 23 ) according to one of the preceding claims, wherein in the coupled state the interior ( 17 ) of the two pipe parts ( 2 . 24 ; 3 ) by the adjoining pipe surfaces even at 0.5 bar overpressure, in particular still at 0.75 bar overpressure, especially at 1 bar overpressure relative to the environment ( 25 ) is sealed.

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